Method for controlling resource utilization and computer system

ABSTRACT

In one embodiment, a method comprises (i) identifying a group associated with an executable that is using a resource of a computer system, (ii) decrementing a group utilization limit for the resource when the group utilization limit is greater than zero, (iii) decrementing a utilization reserve for the group when the group utilization limit for the resource equals zero, wherein operations (i)-(iii) are performed by a software routine responsive to system interrupts, and (iv) scheduling another executable to use the resource, wherein the scheduling verifies that (a) the another executable belongs to a group that has a non-zero group utilization limit for the resource or (b) the another executable belongs to a group that has a non-zero utilization reserve.

TECHNICAL FIELD

The present application is generally related to controlling resource utilization in a computer system.

BACKGROUND

It is frequently desirable to place computer executables into distinct groups. The groups may be defined by user login identifier(s), user classes (e.g., student, teacher, administrator, etc.), application name, and/or the like. Additionally, in a shared computing environment running multiple executables, it is often advantageous for computer managers to place a limit on resource utilization by executables based on the group classifications of the executables. The limitations can be used for program predictability, to maintain isolation between groups, capacity management, or to ensure that users only receive the service level to which they are entitled. In known computing systems such limitations are frequently encoded as “shares” (maximum shares of a limited resource) and are sometimes referred to as “caps.”

A number of technologies have been implemented to enforce share allocation schemes. However, known technologies impose significant overhead thereby reducing application performance. Moreover, known technologies cause additional reductions in performance upon certain combinations of applications within respective groups. For example, using known capping technologies, it is possible that a single executable of a group may consume all of the resources (e.g., processor cycles) assigned to the group before another executable of the same group has an opportunity to access the resource. The other executables of the same group may then not have an opportunity to obtain processor resources for several minutes.

SUMMARY

In one embodiment, a method comprises (i) identifying a group associated with an executable that is using a resource of a computer system, (ii) decrementing a group utilization limit for the resource when the group utilization limit is greater than zero, (iii) decrementing a utilization reserve for the group when the group utilization limit for the resource equals zero, wherein operations (i)-(iii) are performed by a software routine responsive to system interrupts, and (iv) scheduling another executable to use the resource, wherein the scheduling verifies that (a) the another executable belongs to a group that has a non-zero group utilization limit for the resource or (b) the another executable belongs to a group that has a non-zero utilization reserve.

In another embodiment, a computer readable medium comprises a first software routine that (i) determines a respective processor utilization limit for each of a plurality of processors and for each of a plurality of groups and (ii) determines a utilization reserve parameter for each of the plurality of groups, a second software routine that (i) identifies groups of executables that are using the plurality of processors, (ii) decrements respective processor utilization limits of identified groups when processor utilization limits are greater than zero, and (iii) decrements utilization reserve parameters of identified groups, when processor utilization limits of identified groups equal zero, wherein the second software routine is called in response to system interrupts, and a third software routine for scheduling executables to run on the plurality of processors, wherein the third software routine, when an executable is selected for a processor, is operable to verify that (i) the selected executable belongs to a group having a processor utilization limit for the processor that is greater than zero or (ii) the executable belongs to a group having a utilization reserve that is greater than zero.

In another embodiment, a computer system comprises means for identifying a group associated with an executable using a processor of the computer system, means for decrementing a group utilization limit for the processor when the group utilization limit is greater than zero, means for reducing a utilization reserve for the group when the group utilization limit for the processor, wherein the means for identifying, means for decrementing, and means for reducing are operable in response to system interrupts, and means for scheduling another executable to use the processor, wherein the means for scheduling verifies that (a) the another executable belongs to a group that has a non-zero group utilization limit for the processor or (b) the another executable belongs to a group that has a non-zero utilization reserve.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 depicts a system that allocates resources according to one representative embodiment.

FIG. 2 depicts a flowchart for determining amounts of CPU resources measured in clock ticks for allocation to a plurality of groups of executables according to one representative embodiment.

FIG. 3 depicts a flowchart for accounting for resource utilization according to one representative embodiment.

FIG. 4 depicts a flowchart for selecting an executable to be placed on a CPU according to one representative embodiment.

DETAILED DESCRIPTION

Some representative embodiments are directed to systems and methods for limiting resource utilization according to a share or cap based scheme. Specifically, processes are organized into groups and each group is provided a share of a resource or resources. The resources may include processor time, disk bandwidth of a shared channel, network bandwidth on a shared port, or any other resource that can be expressed in shares per unit of time. For the purposes of this discussion, only processor resources shall be discussed. However, representative embodiments are not so limited.

At a predefined interval (e.g., once per second), an allocator software module is executed to determine what allocation of resources to the groups is “fair” on a per group basis and a per processor level. A total number of clock “ticks” available to each group is calculated using the total number of available processors and each group's share. A tick is a known term that is related to the time between system interrupts and, in many systems, system interrupts occur at fixed intervals. For example, in recent Linux systems, system interrupts occur 1000 times per second. However, solely for the purpose of the present discussion, it is assumed that system interrupts occur 100 times per second. The portion of the total number of ticks for each group are divided between the processors assigned to each group. Each group is then allowed the number of calculated ticks (the group processor limit) on the assigned processor. Additionally, a portion of the total number of ticks of each group are assigned to a “charity” reserve for newly instantiated executables or old executables that were instantiated under a prior set of allocation rules. The charity reserves enable selected processes, that would otherwise not receive access to a processor, to make a degree of forward progress.

Upon each interrupt, an accountant software module is executed. Using the respective groups, the accountant software module attributes a tick for each processor. When a group processor limit is reached by a group on a given processor, the accountant software module determines whether any ticks remain in the group's charity reserve. If so, the group's charity reserve is reduced. If the processor limit is reached and the charity reserve is depleted, the executable is switched off the processor. Also, in one embodiment, a scheduler software module performs a second tier of share enforcement. The scheduler software module is used to decide which executable is next to be run on the processor. The scheduler software module does not allow an executable associated with a group that has reached the group processor limit to be selected when the group's charity reserve is depleted.

Referring now to the drawings, FIG. 1 depicts system 100 that allocates processor resources according to one representative embodiment. Specifically, system 100 includes a plurality of executables (shown as applications 102-1 through 102-M) that are executed on CPUs 101-1 through 101-N. System 100 includes operating system 110 that includes software routines within the operating system kernel for determining which applications 102 are to be executed on which CPUs 101.

As shown in FIG. 1, operating system 110 includes allocator software module 111. Allocator software module 111 is used to determine how processing resources are to be allocated within respective predetermined periods. In one embodiment, allocator software module 111 is called once per second and determines the allocation of processor resources for the next second as measured by the system clock. Allocator software module 111 allocates processor resources upon the basis of groups. In one embodiment, a suitable data structure 120 is maintained to define the groups and the shares of resources associated with each group. The data structure 120 may also contain information indicating which CPUs 101 are assigned to execute executables belonging to particular groups. When an executable is created (e.g., by a “fork” command or other suitable command), the characteristics of the executable are analyzed (e.g., user login ID, class of the user, the filename of the executable, and/or the like). Depending upon the analysis, the data structure (not shown) associated with the process is updated to reflect the appropriate group.

Each time allocator software module 111 is called, allocator software module 111 calculates the total amount of processor resources available for each group for the next allocation period using the share information stored in data structure 120. Depending upon which groups are assigned to which CPUs 101, it is possible that the groups assigned to a given CPU 101 may possess a total of more than 100 ticks. Accordingly, allocator software module 111 may normalize the ticks on a per CPU basis. Additionally, allocator software module 111 also assigns a portion of the processor cycles to a charity reserve for each group. In one embodiment, the charity reserve is applied across CPUs 101. The charity reserve enables new executables that were created after the start of the allocation period to obtain processor resources. Also, the charity reserve enables older executables that were instantiated before a change in system allocation characteristics to obtain processor resources. Accordingly, such executables are prevented from “starving” and are allowed to make some forward progress The allocation data may be stored in a suitable data structure (shown as structure 130 in FIG. 1).

To illustrate the generation of allocation data according to one representative embodiment, it is assumed that system 100 includes four CPUs 101. Also, it is assumed that a “students” group is assigned a 51% cap of the system processor resources. Using the formula “group_limit=cap*number_of_processors*100” to generate the group ticks cap, the student group is assigned 204 clock ticks. In one embodiment, the greater of one clock tick and 1% of the group limit is “donated” to the charity reserve. For the student group, 2 clock ticks are assigned to the student charity reserve. The remaining clock ticks are then divided between CPUs 101. If the student group is assigned to execute on only three CPUs (101-1 through 101-3), 67 ticks are provided to each of the CPUs for the student group. The additional clock tick omitted due to rounding is donated to the student charity reserve.

It is further assumed that an “administrator” group receives a 10% cap and is assigned to execute on only CPU 101-1. The administrator group then receives 40 clock ticks (4*100*0.10). One of those clock ticks is donated to the administrator charity reserve. As previously noted, 67 clock ticks on CPU 101-1 have already been assigned. Specifically, a total of 106 (39+67) ticks of time to be performed per second have been assigned for CPU 101-1 with only 100 ticks available for CPU 101-1. Accordingly, normalization preferably occurs to ensure that only 100 clock ticks are assigned per CPU 101. Any rounding excess generated by the normalization operation is redistributed to the charity reserve.

It is also assumed that a “miscellaneous” group receives a 25% cap (100 ticks) and is assigned to CPU 101-4 with one clock tick donated to the miscellaneous charity reserve.

The following table summarizes the ticks calculated for the various groups and charity reserves: CPU 1 CPU 2 CPU 3 CPU 4 RESERVE Student 63 67 67 0 7 Admin 37 0 0 0 3 Miscellaneous 0 0 0 99 1 Unused 56

A system interrupt occurs in system 100 of FIG. 1 every tick and accountant software module 112 is called to enforce the clock tick limitations. Accountant software module 112 determines which executables are on the respective CPUs 101 and determines to which groups the executables belong. For each CPU 101, accountant software module 112 decrements the previously calculated group ticks. When a group tick count reaches zero for a particular group and CPU 101, account software module 112 determines whether there are ticks within the per-group charity reserve. If so, the current executable is allowed to continue and the charity reserve is decremented. When a group tick count for a respective CPU 101 and group reaches zero and the charity reserve also reaches zero, the executable belonging to that group is switched off the respective CPU 101.

Scheduler software module 113 determines which executable is next when an executable is switched off a CPU 101, an executable completes its operations, the executable enters a sleep state, and/or the like. Scheduler software module 113 may maintain a run queue (shown as 114-1 through 1 14-N) for each CPU 101 to perform the scheduling determination. Scheduler module 113 may be implemented using known scheduler algorithms except scheduler module 113 verifies that the next executable belongs to a group having ticks remaining on the respective CPU or ticks remain in the charity reserve. Also, if there are no jobs of a given group left on a respective CPU 101, the group's remaining ticks are provided to the charity reserve.

FIG. 2 depicts a flowchart for determining amounts of CPU resources measured in clock ticks for allocation to a plurality of groups of executables according to one representative embodiment. The operations shown in FIG. 2 may be implemented using suitable code or software instructions within allocator software module 111. The code or software instructions can be stored on any suitable computer readable medium. In one embodiment, the operations shown in FIG. 2 are performed once per second.

In step 201, group cap information is retrieved from a suitable data structure. In step 202, a total number of group ticks for the next allocation period is calculated using total CPU availability and the group cap information. A percentage of the total group ticks are assigned to respective per-group charity reserves (step 203). In step 204, the total group ticks are divided between individually assigned CPUs for each group. In step 205, the group ticks are normalized to ensure that the total group ticks for each individual CPU does not exceed the availability of ticks for the respective CPU. Any rounding errors that result from the preceding calculations may be donated to the charity reserves.

FIG. 3 depicts a flowchart for accounting for CPU utilization according to one representative embodiment. The operations shown in FIG. 3 may be implemented using suitable code or software instructions within accountant software module 112. The code or software instructions can be stored on any suitable computer readable medium. In one embodiment, the operations shown in FIG. 3 are performed upon each system interrupt.

In step 301, a CPU is selected for examination. In step 302, a logical comparison is made to determine whether there is any allocation for a group or groups without jobs on the CPU. If so, the process flow proceeds to step 303 where the per-group allocation is transferred to the respective charity reserve(s). If not, the process flow proceeds to step 304.

In step 304, the group of the executable currently using the CPU is determined. In step 305, a logical comparison is made to determine whether the group's tick count for the CPU is greater than zero. If so, the process flow proceeds to step 306 where the group's tick count is decremented. If not, the process flow proceeds to step 307 where another logical comparison is made to determine if the group's charity reserve is equal to zero. If the charity reserve does not equal zero, the charity reserve is decremented (step 308). If the charity reserve equals zero, the executable is switched off the CPU (step 310).

The process flow transitions from each of steps 306 and 308 to step 309. In step 309, a logical comparison is made to determine whether another group is waiting to use the CPU. If yes, the current executable is switched off the CPU (step 310) to allow an executable of another group to access to the CPU pursuant to a scheduling algorithm. If not, the process flow proceeds to step 311. In step 311, a logical comparison is made to determine whether there is another CPU to be examined. If so, the process flow returns to step 301. If not, the process flow ends (step 312).

FIG. 4 depicts a flowchart for selecting an executable to be placed on a CPU according to one representative embodiment. The operations shown in FIG. 4 may be implemented using suitable code or software instructions within scheduler software module 113. The code or software instructions can be stored on any suitable computer readable medium. The operations shown in FIG. 4 may be performed when an executable terminates, an executable is placed into a sleep state, an executable is switched off the CPU (see step 310 of FIG. 3), and/or the like.

In step 401, an executable is selected from the run queue of a respective CPU according to a known or later developed scheduling algorithm. In step 402, a logical comparison is made to determine if the executable belongs to a group having non-zero ticks for the respective CPU. If so, the executable is placed on the CPU (step 404). If not, another a logical comparison is made in step 403. In step 403, a logical comparison is made to determine whether the executable belongs to a group having non-zero charity reserve. If so, the executable is placed on the CPU (step 404). If not, the process flow returns to step 401 to select another executable.

Some representative embodiments provide a number of advantages. For example, some representative embodiments involve a relatively high precision for allocation and accounting operations. Additionally, some representative embodiments impose relatively low overhead on system resources to manage utilization operations. Application performance is not appreciably hindered. Also, the low overhead allows for large multiprocessor scaling to occur in an efficient manner. Unlike known workload management (WLM) capping technologies, some representative embodiments provide fair allocation to executables within an accuracy of approximately one-half percent over one second. Accordingly, some representative embodiments exhibit appreciable improved performance given that approximately 95 percent of UNIX processes complete in under one second. Additionally, IO intensive workloads exhibit significantly improved performance according to some representative embodiments, because a group can request resources when needed instead of being forced into an arbitrary pre-defined scheduling slot. 

1. A method, comprising: (i) identifying a group associated with an executable that is using a resource of a computer system; (ii) decrementing a group utilization limit for said resource when said group utilization limit is greater than zero; (iii) decrementing a utilization reserve for said group when said group utilization limit for said resource equals zero, wherein operations (i)-(iii) are performed by a software routine responsive to system interrupts; and (iv) scheduling another executable to use said resource, wherein said scheduling verifies that (a) said another executable belongs to a group that has a non-zero group utilization limit for said resource or (b) said another executable belongs to a group that has a non-zero utilization reserve.
 2. The method of claim 1 further comprising: (v) determining a number of resources available in said computer system; (vi) multiplying said number by a share limitation associated with said group to generate a group total limit; and (vii) dividing said group total limit between resources assigned to said group to generate said group utilization limit for an allocation period.
 3. The method of claim 2 further comprising: subtracting a part of said group total limit for assignment to said utilization reserve, wherein said subtracting is performed prior to said dividing.
 4. The method of claim 2 further comprising: normalizing said group utilization limit for said resource, when said group utilization limit and group utilization limits for other groups for said resource exceed a total utilization amount available for said resource.
 5. The method of claim 2 wherein (v)-(vii) are performed by another software routine that is called once per allocation period.
 6. The method of claim 5 wherein said allocation period is one second.
 7. The method of claim 5 wherein said group utilization limit and said utilization encoded represent ticks of said computer system for use by executables of said group.
 8. The method of claim 1 wherein said software routine is within a kernel of an operating system of said computer system.
 9. The method of claim 1 wherein said resource is a processor of said computer system.
 10. A computer readable medium, comprising: a first software routine that (i) determines a respective processor utilization limit for each of a plurality of processors and for each of a plurality of groups and (ii) determines a utilization reserve parameter for each of said plurality of groups; a second software routine that (i) identifies groups of executables that are using said plurality of processors; (ii) decrements respective processor utilization limits of identified groups when processor utilization limits are greater than zero; and (iii) decrements utilization reserve parameters of identified groups, when processor utilization limits of identified groups equal zero, wherein said second software routine is called in response to system interrupts; and a third software routine for scheduling executables to run on said plurality of processors, wherein said third software routine, when an executable is selected for a processor, is operable to verify that (i) said selected executable belongs to a group having a processor utilization limit for said processor that is greater than zero or (ii) said executable belongs to a group having a utilization reserve that is greater than zero.
 11. The computer readable medium of claim 10, wherein said first software routine retrieves a share parameter for each group and multiplies said share parameter by the number of said plurality of processors to calculate a total group processor limit.
 12. The computer readable medium of claim 11 wherein said first software routine subtracts an amount from said total group processor limit for said utilization reserve parameter.
 13. The computer readable medium of claim 12 wherein said first software routine divides a respective total group processor limit by a number of processors assigned to a group to calculate a processor utilization limit after subtracting said amount.
 14. The computer readable medium of claim 10 wherein said first software routine normalizes processor utilization limits for a respective processor when processor utilization limits for multiple groups assigned to said respective processor exceed an amount available for said respective processor.
 15. The computer readable medium of claim 10 wherein said first software routine is called once per allocation period.
 16. The computer readable medium of claim 15 wherein said allocation period is one second.
 17. The computer readable medium of claim 10 wherein said processor utilization limits and said utilization reserve parameters encode ticks of said computer system for use by executables of said plurality of groups.
 18. A computer system, comprising: means for identifying a group associated with an executable using a processor of said computer system; means for decrementing a group utilization limit for said processor when said group utilization limit is greater than zero; means for reducing a utilization reserve for said group when said group utilization limit for said processor, wherein said means for identifying, means for decrementing, and means for reducing are operable in response to system interrupts; and means for scheduling another executable to use said processor, wherein said means for scheduling verifies that (a) said another executable belongs to a group that has a non-zero group utilization limit for said processor or (b) said another executable belongs to a group that has a non-zero utilization reserve.
 19. The computer system of claim 18 wherein said group utilization limit encodes a number of system ticks for use by said group.
 20. The computer system of claim 18 further comprising: means for removing an executable from said processor when said executable belongs to a group having a group utilization limit for said processor that equals zero and a utilization reserve that equals zero. 